A platform for research: civil engineering, architecture and urbanism
A platform for research: civil engineering, architecture and urbanism
Spaceborne detection of XCO2 enhancement induced by Australian mega-bushfires
The 2019–20 Australian mega-bushfires, which raged particularly over New South Wales and Victoria, released large amounts of toxic haze and CO _2 . Here, we investigate whether the resulting CO _2 enhancement can be directly detected by satellite observations, based on National Aeronautics and Space Administration’s Orbiting Carbon Observatory-2 (OCO-2) column-averaged CO _2 (XCO _2 ) product. We find that smoke from wildfires can greatly obscure satellite observations, making the available XCO _2 mainly locate over outer fringes of plumes downwind of the major mega-bushfires in eastern Australia in three orbit observations during November–December 2019, with their enhancements of approximately 1.5 ppm. This fire-induced CO _2 enhancement is further confirmed using an atmospheric transport model, Goddard Earth Observing System-Chem, forced by satellite observation-derived fire product Global Fire Emissions Database, version 4.1 and wind observations, with comparable simulated XCO _2 enhancements. Model simulation also suggests that the sensitivity of the downwind maximum XCO _2 enhancement is 0.41 $ \pm \,$ 0.04 ppm for 1 TgC d ^−1 fire emissions. In sum, though detectable to some extent, it remains a challenge to get the accurate maximum XCO _2 enhancements due to the gaps in XCO _2 detections obscured by smoke. Understanding the capability of OCO-2 XCO _2 detection is prerequisite for monitoring and constraining wildfire CO _2 emissions by inversions.
Spaceborne detection of XCO2 enhancement induced by Australian mega-bushfires
The 2019–20 Australian mega-bushfires, which raged particularly over New South Wales and Victoria, released large amounts of toxic haze and CO _2 . Here, we investigate whether the resulting CO _2 enhancement can be directly detected by satellite observations, based on National Aeronautics and Space Administration’s Orbiting Carbon Observatory-2 (OCO-2) column-averaged CO _2 (XCO _2 ) product. We find that smoke from wildfires can greatly obscure satellite observations, making the available XCO _2 mainly locate over outer fringes of plumes downwind of the major mega-bushfires in eastern Australia in three orbit observations during November–December 2019, with their enhancements of approximately 1.5 ppm. This fire-induced CO _2 enhancement is further confirmed using an atmospheric transport model, Goddard Earth Observing System-Chem, forced by satellite observation-derived fire product Global Fire Emissions Database, version 4.1 and wind observations, with comparable simulated XCO _2 enhancements. Model simulation also suggests that the sensitivity of the downwind maximum XCO _2 enhancement is 0.41 $ \pm \,$ 0.04 ppm for 1 TgC d ^−1 fire emissions. In sum, though detectable to some extent, it remains a challenge to get the accurate maximum XCO _2 enhancements due to the gaps in XCO _2 detections obscured by smoke. Understanding the capability of OCO-2 XCO _2 detection is prerequisite for monitoring and constraining wildfire CO _2 emissions by inversions.
Spaceborne detection of XCO2 enhancement induced by Australian mega-bushfires
Jun Wang (author) / Zhiqiang Liu (author) / Ning Zeng (author) / Fei Jiang (author) / Hengmao Wang (author) / Weimin Ju (author)
2020
Article (Journal)
Electronic Resource
Unknown
Metadata by DOAJ is licensed under CC BY-SA 1.0
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